substrates having molded dielectric layers and methods of fabricating such substrates are disclosed. The substrates may advantageously be used in microelectronic assemblies having high routing density.
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1. A microelectronic substrate having a plurality of traces configured for coupling with external contacts of a microelectronic element mountable thereto, comprising:
a plurality of solid metal first contact pins, each first pin having a base and a tip;
a plurality of first conductive elements including conductive traces and conductive contact areas configured for electrical connection with the microelectronic element mountable thereto, at least some of the first conductive elements being coupled to the bases of the first pins so that the first pins project downwardly from the first conductive elements; and
a molded dielectric layer disposed in regions around the first pins and contacting the first pins, the molded dielectric layer having an exposed bottom surface coplanar with the tips of the first pins, and a top surface opposed to the bottom surface, wherein the first conductive elements extend along the top surface of the molded dielectric layer, and at least some of the tips of the first pins are exposed at the bottom surface of the dielectric layer, wherein the molded dielectric layer comprises epoxy.
15. A microelectronic substrate having a plurality of traces for electrical interconnection with external contacts of a microelectronic element mountable thereto, comprising:
a plurality of solid metal first contact pins, each first pin having a base and a tip;
a plurality of first conductive elements including conductive traces and conductive contact areas adapted for electrical connection with the microelectronic element mountable thereto, at least some of the first conductive elements being coupled to the bases of the first pins so that the first pins project downwardly from the first conductive elements;
a molded dielectric layer disposed in regions around the first pins and contacting the first pins, the molded dielectric layer having an exposed bottom surface coplanar with the tips of the first pins, a top surface opposed to the bottom surface, wherein the first conductive elements extend along the top surface of the molded dielectric layer, and at least some of the tips of the first pins are exposed at the bottom surface of the molded dielectric layer; and
a solid metal spacer extending in a first direction parallel to the top and bottom surfaces of the molded dielectric layer, said spacer having a dimension in said first direction greater than a distance between two adjacent first pins of said first pins, said spacer having a top surface coplanar with said top surface of said molded dielectric layer and having a bottom edge coplanar with said bottom surface of said molded dielectric layer and said tips of said first pins.
2. The substrate of
6. The substrate of
8. The substrate of
9. The substrate of
10. The substrate of
11. The substrate of
16. The substrate of
17. The substrate of
18. The substrate of
20. The substrate of
21. A unit comprising the substrate of
22. An assembly including a plurality of units as claimed in
23. The microelectronic substrate of
24. The microelectronic substrate of
25. The microelectronic substrate of
26. The microelectronic substrate of
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The present application is a continuation of U.S. patent application Ser. No. 13/277,404, filed on Oct. 20, 2011, which application is a continuation of U.S. patent application Ser. No. 12/830,690, filed on Jul. 6, 2010, now U.S. Pat. No. 8,071,424 issued on Dec. 6, 2011. Said U.S. application Ser. No. 12/830,690 is a divisional of U.S. application Ser. No. 11/400,665, filed on Apr. 7, 2006, now U.S. Pat. No. 7,759,782, issued on Jul. 20, 2010. The disclosures of all said applications are incorporated herein by reference.
The present invention generally relates to microelectronic assemblies and, in particular, to substrates used in microelectronic assemblies and methods of fabricating such substrates.
Circuit panels or substrates are widely used in electronic assemblies. Typical circuit panels commonly include a dielectric element in the form of a sheet or plate of dielectric material having numerous conductive traces extending on the sheet or plate. The traces may be provided in one layer or in multiple layers, separated by layers of dielectric material. The circuit panel or substrate may also include conductive elements such as via liners extending through the layers of dielectric material to interconnect traces in different layers. Some circuit panels are used as elements of microelectronic packages. Microelectronic packages generally comprise one or more substrates with one or more microelectronic devices such as one or more semiconductor chips mounted on such substrates. The conductive elements of the substrate may include the conductive traces and terminals for making electrical connection with a larger substrate or circuit panel, thus facilitating electrical connections needed to achieve desired functionality of the devices. The chip is electrically connected to the traces and hence to the terminals, so that the package can be mounted to a larger circuit panel by bonding the terminals to contact pads on the larger circuit panel. For example, some substrates used in microelectronic packaging have terminals in the form of pins extending from the dielectric element.
Despite considerable efforts devoted in the art heretofore to development of substrates and methods for fabricating such substrates, further improvement would be desirable.
One aspect of the present invention provides a method for fabricating a substrate for a microelectronic package. The method desirably comprises forming a molded dielectric layer which surfaces are coplanar with bases and tips of conductive pins of the substrate. Conductive traces may be formed on one or both sides of the dielectric layer.
Other aspects of the present invention provide substrates such as those fabricated using the disclosed method. Still further aspects of the invention provide microelectronic packages and assemblies which include one or more such substrates.
The Summary is neither intended nor should it be construed as being representative of the full extent and scope of the present invention, which additional aspects will become more readily apparent from the detailed description, particularly when taken together with the appended drawings.
Herein, identical reference numerals are used, where possible, to designate identical elements that are common to the figures. The images in the drawings are simplified for illustrative purposes and are not depicted to scale.
The appended drawings illustrate exemplary embodiments of the invention and, as such, should not be considered as limiting the scope of the invention that may admit to other equally effective embodiments.
The method 100 starts at step 102 and proceeds to step 104. A method according to one embodiment of the invention uses a conductive plate 200 having a perimeter 202 (
At step 106, a plurality of conductive pins 210 and at least one optional spacer 212 are formed on the plate 200 (
The spacer 212 generally has a closed-loop wall-like form factor and is disposed around an individual section of plate 200 or near the perimeter 202 (as shown), thus surrounding at least some of the pins 210, as illustratively depicted in a bottom plan view (
The pins 210 are formed at locations facilitating connectivity between elements of an electrical circuit of the substrate being fabricated. Such pins may have different form factors and be organized, for example, in one or more grid-like patterns having a pitch in a range from 100 to 10000 μm (e.g., 400-650 μm).
In the next stage of the method, at step 108, a molded dielectric layer 220 is formed on the plate 200 (
For example, compositions which cure by chemical reaction to form a polymeric dielectric, such as epoxies and polyimides may be used. In other cases, the flowable composition may be a thermoplastic at an elevated temperature, which can be cured to a solid condition by cooling. Preferably, the layer 220, after molding, forms binding interfaces with features of the plate 200. The composition may further include one or more additives influencing properties of the layer 220. For example, such additives may include particulate materials such as silica or other inorganic dielectrics, or fibrous reinforcements such as short glass fibers.
During the molding processes, the plate 200 is sandwiched between a press plate 214 and a counter element 216 (shown using phantom lines) which in this embodiment is part of a molding tool (
In the particular embodiment depicted in
In a variant of the molding step, the composition may be injected through the slots 218 in the spacer, and openings 217 in the counter element may serve as a vent. Alternatively, one or more openings (not shown) can be formed through layers 204 and 208 of the plate, and these openings may serve either as injection openings for the composition or as vents. In yet another variant, the composition may be provided as a mass disposed on the tips of the pins or on counter element 216 before the counter element is engaged with the tips of the pins, so that the composition is forced into the spaces between the pins as the pins are brought into abutment with the counter element. In another variant, when the plate 200 includes multiple spacers 212 defining individual sections of the plate, the openings 217 may selectively be associated with such sections.
In another embodiment, the plate 200 may be a portion of a larger frame 242 incorporating a plurality of the plates 200 (
The molding step forms the dielectric element, or dielectric layer, with a bottom surface 226 coplanar with the tips 210B of the pins and coplanar with the tip 212B of the spacer (
At step 110, conductive traces 230 are formed from the layers 204 and 206 using, e.g., an etch process (
At least one trace 230 may be a peripheral trace 230A having a closed-loop pattern and surrounding at least some of pins or other traces as illustratively shown in
The traces 230 may have different widths, including the widths which are smaller than the widths of the bases 210A and tips 210B of the pins 210 (as shown in
A substrate 340A according to a further embodiment has a recess 302 formed in a central region, recess 302 being open to the bottom surface 226 of the dielectric layer. Such a substrate can be formed by a process substantially as discussed above with reference to
In a substrate 340B of the embodiment of
Alternatively, the dielectric layer may be fabricated using a counter element without such a projection, so that the entire bottom surface as molded is flat, and then machined or etched to form the recess 302 or opening 306. In further variants, two or more recesses may be provided in the dielectric layer. Also, the recess need not be provided in a central region of the substrate.
A substrate 440 according to a further embodiment of the invention is fabricated using a conductive plate 400 having a single layer 406 of the principal metal (e.g., Cu and the like) (
A substrate according to yet another embodiment of the invention is fabricated using two conductive plates 200 and 500 (
Then, conductive traces 530 are fabricated from the plate 500 (
A process according to a further embodiment uses two conductive plates. Illustratively, such plates are multi-layered plates 200A and 200B (
Pins 210 are fabricated in the plate 200A as discussed above in reference to
Since the pins are tapered (i.e., tips of the pins are smaller than their bases), in such a substrate the interspersed pins may be disposed closer to one another than the pins formed on the same plate, thus increasing density of the conductive pins in the substrate being fabricated. The tips 210B of the pins on the first plate 200A are abutted against the second plate 200B, whereas the tips 610B of the pins on the second plate are abutted against the first plate 200A. Then, using a conventional metal-coupling process, the tips 210B of the pins 210 are connected to the plate 200B and the tips 610B of the pins 610 are connected to the plate 200A, respectively.
The dielectric layer 220 is molded in the space between the plates (
A process according to another embodiment uses the press plate and counter element forming, around a perimeter of the substrate being fabricated, an enclosure for the molding composition. The substrates may be fabricated with a peripheral spacer (substrate 740A in
A process according to yet further embodiment uses a single plate 804 (
Substrates fabricated according to yet further embodiments the method of
Microelectronic elements, or devices, may be mounted on the substrates using techniques such as a ball-bonding and/or wire-bonding technique. In
More specifically, the
The substrates discussed above may be interconnected to form multi-substrate structures.
Although the invention herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims.
Haba, Belgacem, Mitchell, Craig S., Alvarez, Jr., Apolinar
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